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OPEN
received: 23 September 2016
accepted: 09 December 2016
Published: 19 January 2017
Leads in Arctic pack ice enable
early phytoplankton blooms below
snow-covered sea ice
Philipp Assmy1, Mar Fernández-Méndez1, Pedro Duarte1, Amelie Meyer1, Achim Randelhoff1,2,
Christopher J. Mundy3, Lasse M. Olsen1, Hanna M. Kauko1, Allison Bailey1, Melissa Chierici4,
Lana Cohen1, Anthony P. Doulgeris5, Jens K. Ehn3, Agneta Fransson1, Sebastian Gerland1,
Haakon Hop1,2, Stephen R. Hudson1, Nick Hughes6, Polona Itkin1, Geir Johnsen7,8,
Jennifer A. King1, Boris P. Koch9, Zoe Koenig10, Slawomir Kwasniewski11, Samuel R. Laney12,
Marcel Nicolaus9, Alexey K. Pavlov1, Christopher M. Polashenski13, Christine Provost10,
Anja Rösel1, Marthe Sandbu7, Gunnar Spreen1,14, Lars H. Smedsrud15,16, Arild Sundfjord1,
Torbjørn Taskjelle17, Agnieszka Tatarek11, Jozef Wiktor11, Penelope M. Wagner6, Anette Wold1,
Harald Steen1 & Mats A. Granskog1
The Arctic icescape is rapidly transforming from a thicker multiyear ice cover to a thinner and largely
seasonal first-year ice cover with significant consequences for Arctic primary production. One critical
challenge is to understand how productivity will change within the next decades. Recent studies have
reported extensive phytoplankton blooms beneath ponded sea ice during summer, indicating that
satellite-based Arctic annual primary production estimates may be significantly underestimated. Here
we present a unique time-series of a phytoplankton spring bloom observed beneath snow-covered
Arctic pack ice. The bloom, dominated by the haptophyte algae Phaeocystis pouchetii, caused near
depletion of the surface nitrate inventory and a decline in dissolved inorganic carbon by 16 ± 6 g C m−2.
Ocean circulation characteristics in the area indicated that the bloom developed in situ despite the
snow-covered sea ice. Leads in the dynamic ice cover provided added sunlight necessary to initiate and
sustain the bloom. Phytoplankton blooms beneath snow-covered ice might become more common and
widespread in the future Arctic Ocean with frequent lead formation due to thinner and more dynamic
sea ice despite projected increases in high-Arctic snowfall. This could alter productivity, marine food
webs and carbon sequestration in the Arctic Ocean.
Annual phytoplankton net primary production in the Arctic Ocean has increased by 30% since the late 1990’s
mainly due to the declining sea ice extent and an increasing phytoplankton growth season1. However, there is
considerable uncertainty about the future change in Arctic Ocean primary productivity largely attributed to the
1
Norwegian Polar Institute, Fram Centre, 9296 Tromsø, Norway. 2Department of Arctic and Marine Biology, Faculty
of Biosciences, Fisheries and Economics, UiT The Arctic University of Norway, 9037 Tromsø, Norway. 3Centre for
Earth Observation Science, University of Manitoba, Winnipeg, MB R3T 2N2, Canada. 4Institute of Marine Research,
9019 Tromsø, Norway. 5Department of Physics and Technology, Faculty of Science and Technology, UiT The Arctic
University of Norway, 9037 Tromsø, Norway. 6Norwegian Meteorological Institute, 9239 Tromsø, Norway. 7Centre
for Autonomous Marine Operations and Systems, Department of Biology, Norwegian University of Science and
Technology, 7491 Trondheim, Norway. 8University Centre in Svalbard, Post box 156, 9171 Longyearbyen, Norway.
9
Alfred Wegener Institute, Helmholtz Center for Polar and Marine Research, 27570 Bremerhaven, Germany.
10
LOCEAN, UMR 7159, CNRS/UPMC/MNHN/IRD, Pierre and Marie Curie University, Paris cedex, France. 11Institute of
Oceanology, Polish Academy of Sciences, 81-712 Sopot, Poland. 12Biology Department, Woods Hole Oceanographic
Institution, Woods Hole, MA 02543, USA. 13U.S. Army, Cold Regions Research and Engineering Laboratory, Hanover,
NH 03755, USA. 14Institute of Environmental Physics, University of Bremen, 28334 Bremen, Germany. 15Bjerknes
Centre for Climate Research, 5007 Bergen, Norway. 16Geophysical Institute, University of Bergen, 5007 Bergen,
Norway. 17Department of Physics and Technology, University of Bergen, 5007 Bergen, Norway. Correspondence and
requests for materials should be addressed to P.A. (email: Philipp.Assmy@npolar.no)
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different representation of the intricate balance between nutrient and light availability in coupled physical and
biological ocean models2,3. The sea ice zone was identified as the area with largest model uncertainty2. Thus, a
better understanding of the processes that control primary productivity in ice-covered waters will help to reduce
this uncertainty.
Phytoplankton production beneath the ice-covered Arctic Ocean is assumed negligible because of the strong
light attenuation properties of snow and sea ice, despite sporadic reports of phytoplankton growth beneath Arctic
sea ice over the past decades4–8. This paradigm has recently been challenged by observations of under-ice phytoplankton blooms during the summer melt season9–12. In these studies, snowmelt onset and subsequent melt-pond
formation permitted sufficient light transmission through the consolidated ice cover to trigger diatom-dominated
phytoplankton blooms fuelled by underlying nutrient-rich waters9–12. In areas where extensive diatom blooms
under thinning Arctic ice cover occur, current satellite-based estimates of annual primary production could be
underestimated by an order of magnitude and change our perception of Arctic marine ecosystems10. In this study,
we show for the first time that an under-ice phytoplankton bloom dominated by Phaeocystis pouchetii was actively
growing beneath snow-covered pack ice at higher latitudes and earlier in the season than previously observed.
We studied the ice-associated ecosystem and the environmental factors shaping it in the Arctic Ocean north of
Svalbard from 11 January to 24 June 2015 during the Norwegian young sea ICE (N-ICE2015) expedition13. Four
ice camps were established during N-ICE201513, but herein we focus on drifts of ice floes 3 and 4 covering early
spring to early summer (Fig. 1a). Chlorophyll (Chl a) concentrations in the water column were low (<​0.5 μ​g L−1)
until 25 May when we first drifted into an under-ice phytoplankton bloom over the Yermak Plateau (YP) 80 km
north of the ice edge (Fig. 1a) and remained within it until the end of the expedition on 22 June (Fig. 1b). The
onset of the bloom coincided with shallowing of the pycnocline (Fig. 1b) and reduction in turbulent mixing
(Table S1). This resulted in an increased residence time in the surface layer and thus light exposure of phytoplankton. Maximum Chl a concentrations of 7.5 μ​g L−1 were observed on 2 June and 50 m depth-integrated Chl a and
particulate organic carbon (POC) standing stocks ranged between 109–233 mg Chl a m−2 and 9–22 g C m−2. The
under-ice bloom (10–80 km from open waters) nearly depleted the surface nitrate inventory (Fig. 1c) and reduced
dissolved inorganic carbon (DIC) at depths down to 50 m (Fig. S1). The depth of nutrient depletion clearly indicates drawdown by phytoplankton rather than ice algal growth. Indeed, the ice algal community, dominated by
pennate diatoms, was distinct from the under-ice bloom. The under-ice bloom was dominated by P. pouchetii
(Fig. 2a), which accounted for 55–92% of phytoplankton abundance and 12–93% of phytoplankton biomass and
occurred both in its flagellate stage (Fig. 2b) and as large colonies (Fig. 2c). Furthermore, ice algal standing stocks
were low (<​3 mg Chl a m−2) throughout the drift indicating that contributions from the ice to water column
stocks were negligible. A detailed list of protist plankton taxa observed during the bloom period can be found in
the Supplementary Information (Table S2).
Regional ice thickness surveys with radius up to 50 km from the ice camp showed a total (ice plus snow)
modal thickness of 1.8 m, with a secondary mode at 0.2 m, representing thin, lead ice (Fig. S2). Local surveys on
floes 3 and 4 agreed, showing a modal ice thickness of 1.46 ±​ 0.66 m for the thick ice, covered by 0.39 ±​ 0.21 m
of snow (Fig. S2), while snow thickness on the thin ice ranged from 0.01–0.06 m. Thus, for modelling of the
under-ice light field and primary production, we treat all ice as being one of these two modal types either ‘thick
ice’ with thick snow cover or ‘thin ice’ representative of recently refrozen leads with thin snow cover. The dominant snow-covered thick ice transmitted, on average, only <​1% of the incident photosynthetic active radiation
(EPAR) to the underlying water column. On the other hand, EPAR transmittance for thin ice examined near camp
in a refrozen lead was 20% on average, ranging from 6.3–42.2%. Leads in the ice pack (Fig. S3) were frequently
created by ice divergence events (Fig. S5) prior to and during the bloom period. This high lead fraction is characteristic of the pack ice north of Svalbard14. Satellite-based ice type classification (Fig. S4 and Table S3) indicated
that open water and thin, newly formed ice covered 1–33% of the area during the bloom period (Fig. 3a). Melt
ponds were not a major factor in light availability during this study. Snowmelt did not start until early June and
melt ponds formed only towards the end of the study period, covering <​10% of the ice surface. We combined the
estimated aerial fractions of open water, thin ice and thick, snow-covered ice with EPAR transmittance through
these surfaces to estimate the aggregate light field (Fig. 3a and Figs S6 and S7) experienced by phytoplankton.
The growth potential of P. pouchetii was modelled based on 14C photosynthesis-irradiance (PE) relationships
obtained from a P. pouchetii bloom in the Greenland Sea15, taking into account the underwater light field based
on measured16 and modelled irradiance through three different surface types (open water, thin ice with thin
snow cover and thicker ice with thick snow cover) encountered during the study. The primary production (PP)
model supports the observation that the bloom was actively growing beneath the ice despite the low irradiance
(Fig. 3b). This is in accordance with previous studies showing that Phaeocystis is particularly well adapted to
low light environments17,18. In vivo photosynthetic parameters, obtained with the Pulse Amplitude Modulation
(PAM) method to assess the photo-acclimation status of the bloom, corroborate this finding (Table S5). High
maximum quantum yields of charge separation in photosystem II (Chl a fluorescence of dark-acclimated cells) of
0.48–0.66 showed that the bloom-forming species were in good condition and actively growing. The maximum
light utilization coefficient (α​) of 0.188–0.295, obtained from Rapid Light Curves, also illustrates that the bloom
exhibited high photosynthetic rates at low irradiances. Furthermore, the low POC/Chl a ratio of 31.4 in the upper
25 m of the under-ice water column suggests a relatively high investment in photosynthetic pigments, indicative
of shade-acclimation. On the other hand, light saturation (Ek) values of 137–584 μ​mol photons m−2 s−1 suggests
that the phytoplankton community was at the same time acclimated to relatively high irradiances. This apparent
inconsistency can be explained by the plasticity in photosynthetic performance of P. pouchetii that seems to be a
characteristic feature of this species15 promoting its dominance under the highly variable light regime encountered during this study. The relatively minor contribution of diatoms to the under-ice bloom (Fig. 2a), with the
exception of 8 June, is supported by the PP model results (Table S4). Diatoms are usually a major component of
the phytoplankton spring bloom in the marginal ice zone north of Svalbard19 and have been reported to dominate
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Figure 1. Study location and vertical and spatial extent of the under-ice bloom. (a) European Arctic with
bathymetry. Orange and green lines are the drift trajectories of floes 3 and 4, respectively, with start and end
dates. The location when we first drifted into the under-ice bloom on 25 May is indicated with an orange star.
The area demarcating the ice-edge positions between April and June 2015 is shaded in grey. The ice-edge
position on 25 May is indicated by the broken blue line and is representative for the bloom period. We define the
ice edge as the outer perimeter of a polygon where ice concentration is >​10%. The white outline demarcates the
area shown in panels b and c. Map created by the Norwegian Polar Institute, Max König with permission from
IBCAO47. Drift trajectories of floes 3 and 4 showing (b) Chlorophyll a, and (c), nitrate concentrations for the
upper 100 m of the water column. The dashed line in (b) indicates depth of the pycnocline.
under-ice blooms below ponded ice in summer9–12. The dynamic light conditions beneath the snow-covered
drifting pack ice interspersed with transparent leads were apparently not sufficient to sustain growth rates for
diatom bloom build-up20. Silicic acid concentrations in the upper 50 m during the bloom period remained close
to winter values at 4.0 ±​ 0.4 μ​mol L−1 (Fig. S8), suggesting that no substantial diatom growth had taken place in
these waters.
Measurements made with a vessel-mounted profiling current meter during the drifts over the YP indicated
that transport velocities in Polar Surface Water (PSW) were weak. Time-mean current velocity components in
PSW at 20–30 m depth for the bloom period were 2.2 cm s−1 heading nearly due west (Table S6). While these
observations do not explicitly cover areas upstream of the drift itself, they indicate that advection over this part of
YP was very weak during the expedition. An operational ocean model (PSY4, Mercator-Ocean, Table S6) shows
similar, but smaller, net currents due west (Fig. 3c) at the same depth. These simulations do not contain tidal
forcing and thus no tidal residual currents.
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Figure 2. Composition of the under-ice phytoplankton bloom and particulate organic carbon standing stocks.
(a) Integrated stocks of phytoplankton carbon (coloured bars) with contributions of Phaeocystis pouchetii,
diatoms and other phytoplankton and particulate organic carbon (black stars) for the upper 50 m surface layer.
Micrographs of (b), solitary cells (600x magnification) and (c), a colony of P. pouchetii (100x magnification).
Model and observations both suggest that surface waters over the interior YP were not advected from open
water regions. During the bloom, model and observations show the presence of Atlantic Water (AW) masses at
greater depths (Fig. 3d). The overall circulation regime was not favourable for rapid advection of AW from the
main branches of the West Spitsbergen Current into the interior part of the YP. Mean currents on the YP itself
were weak and not capable of advecting substantial volumes of surface waters from the ice edge to the northernmost part of the observed bloom on time scales less than six weeks. Six weeks prior to the observed under-ice
bloom (12 and 13 April), we measured Chl a concentrations of <​0.1 μ​g L−1 in open waters across the shelf slope
north of Svalbard on transit to floe 3. Thus, the weak re-circulation pattern over YP implies that the bloom grew in
situ beneath the ice pack. The area that floes 3 and 4 drifted over towards the end of their respective drifts in June
was open water in mid-April when the ice edge was at its northern-most position during the period April to June
2015 (Fig. 1a and Supplementary Video). Considering the low Chl a concentration measured in April, our observations also discount the alternative explanation that the bloom developed in open waters and was subsequently
covered by drifting sea ice. However, enhanced vertical mixing over the YP21 supports the theory that P. pouchetii
cells were likely mixed upwards from the sub-surface AW into the bloom in the PSW, thus contributing to the
seeding of the bloom. This is consistent with observations that P. pouchetii is affiliated with AW22. Furthermore,
in winter AW can be found close to the surface over the southern parts of YP providing another potential seeding
mechanism.
The mean integrated drawdown of 16 ±​ 6 g C m−2 in the DIC inventory and a nitrate uptake equivalent to 15 ±​ 5 g C
m−2 for the bloom period agreed well with the build-up in POC standing stocks. The biogeochemical footprint
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Figure 3. Primary production model and water mass circulation over the Yermak Plateau. (a) Open water,
thin and thick ice concentration and weight-averaged EPAR right below the sea surface based on the aerial
fractions of the three different surface types. The white and coloured areas represent the area fraction of open
water and sea ice, respectively, derived from satellite data (Supplementary Fig. S4). EPAR values are modelled
from surface EPAR measurements and taking into account the diurnal cycle, different fractions of ice and open
water and their respective optical properties. (b) Temporal evolution of Chl a concentration and net
primary production (NPP) during the bloom period predicted by the model. Map of (c), surface (20 m) and
(d), subsurface (80 m) simulated currents from model outputs with currents >​2 cm s−1. Current velocity is
indicated by the size of the vectors (scale on figure). Black lines show drift trajectories. Colour dots show surface
Chl a concentrations as measured along track indicating the bloom locations. Background colours show surface
and subsurface water masses where blue is Polar Surface Water (PSW) and red is Atlantic Water (AW). Areas
shallower than 20 m (c) and 80 m (d) are white. Topography of the Yermak Plateau is shown as thin black lines
(500, 1000, 2000 and 3000 m). The maps in (c) and (d) were generated with the m-map package of Matlab 8.4
(https://www.eoas.ubc.ca/~rich/map.html).
of the bloom was comparable to a diatom bloom beneath ponded, more transparent sea ice at a lower latitude12.
Carbon export rates at 100 m increased from 74 to 244 mg C m−2 d−1 during the bloom period. Inspection of
100 m depth sediment-trap material revealed that the bulk of vertical carbon export was mediated via P. pouchetii
aggregates, while zooplankton faecal pellets accounted for <​2%. Out of the 63 zooplankton taxa identified in
200 μ​m MultiNet samples taken during the bloom period, the three dominant Calanus species (C. finmarchicus,
C. glacialis and C. hyperboreus) accounted for 89 ±​ 8% of the total zooplankton biomass. The apparently low
grazing impact on the P. pouchetii bloom by the dominant Calanus copepods is supported by the finding that
P. pouchetii does not significantly contribute to Calanus diet23. Daily export rates were low, corresponding to
0.9–2% of POC standing stocks in the upper 100 m. This is consistent with previous measurements from the
Barents Sea24 and supports the finding that P. pouchetii does not contribute much to deep carbon sequestration,
which is generally mediated by diatoms25,26. This is corroborated by the dominance of fatty acid trophic markers
from diatoms, rather than Phaeocystis, in benthic macrofauna27. Significant export of P. pouchetii biomass below
100 m has been reported previously28,29, but has been attributed to downwelling29, deep vertical mixing26 or could
potentially be attributed to other mechanisms facilitating deep export such as mineral ballasting.
Our observations extend the spatial and temporal domains of known under-ice blooms. High lead fraction
provided sufficient light to initiate and sustain an under-ice spring bloom dominated by P. pouchetii, despite the
thick snow cover and limited light transmission. High lead fractions in Fram Strait, the Barents Sea, and in other
parts of the Arctic Ocean14 suggest that early phytoplankton blooms under snow-covered sea ice might be widespread and become more prevalent in the future Arctic Ocean under an increasingly thinner and dynamic ice
cover30 and a projected increase in high-Arctic snowfall31. This trend could be reinforced by the recent increase in
advective transport of AW into the European Arctic32 seeding PSW with shade-adapted P. pouchetii, a conjecture
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that is corroborated by a shift in dominance from diatoms towards P. pouchetii in Fram Strait since 200633–35.
Nutrient depletion by early P. pouchetii blooms under snow-covered sea ice would constrain diatom blooms during the melt season, with far-reaching repercussions on bloom timing and composition, strength of the biological
carbon pump and energy flow through Arctic marine food webs.
Methods
Standard analytical procedures.
Chl a samples were collected on 25-mm GF/F filters (Whatman),
extracted in 100% methanol for 12 h at 5 °C on board the ship and measured fluorometrically with an AU10
Turner Fluorometer (Turner Design, Inc.). Phaeopigments were measured by fluorescence after acidification with
5% HCl. Calibration of the Turner Fluorometer was carried out following the JGOFS protocol36. Chl a measurement uncertainty (5.5% of measured values) was estimated from triplicate water samples taken from depths
ranging between 5 and 100 m. Particulate organic carbon (POC) and particulate organic nitrogen (PON) samples
were collected onto pre-combusted 25-mm GF/F filters (Whatman), dried at 60 °C and stored at room temperature in PALL filter slides until analysis with continuous-flow mass spectrometry (CF-IMRS) carried out with a
Roboprep/tracermass mass spectrometer (Europa Scientific, UK). All POC/N values were corrected for instrument drift and blanks. Water samples for inorganic nutrients were collected in 20 mL scintillation vials, fixed with
0.2 mL chloroform and stored refrigerated until sample analysis approximately 6 months later. Nitrite, nitrate,
phosphate and silicic acid were measured spectrophotometrically at 540, 540, 810 and 810 nm, respectively, on a
modified Scalar autoanalyser. The measurement uncertainty for nitrite is 0.06 μ​mol L−1 and 10% or less for nitrate,
phosphate and silicic acid. Seawater for DIC analyses was sampled in 250 mL borosilicate bottles, preserved with
60 μ​L saturated mercuric chloride solution and stored dark and cool. DIC was determined using gas extraction
followed by colourometric detection37. Certified Reference Material (CRM from A. Dickson at Scripps Institution
of Oceanography, USA) was used for calibration and to check the accuracy of the analysis. The integrated nutrient
drawdown in the upper 50 m for the bloom period was estimated from salinity-normalized (34.33) nDIC and
nNO−
3 (nitrate) for all stations and converted to carbon using the measured POC/PON ratio of 5.7 ±​ 1.3. The
complete N-ICE2015 water column biogeochemical dataset has been published in the Norwegian Polar Data
Centre38.
Sediment traps. Ice-tethered sediment traps (KC Denmark) were deployed four times at 5, 25, 50 and 100 m
depth during the bloom period. Deployment time varied between 36 and 72 h, but was usually close to 48 h.
Before deployment, each trap cylinder was filled with a saturated NaCl solution to reduce microbial activity and
thus increase the retention of organic matter. The traps were carefully deployed and retrieved to avoid loss of
trap material. Swimmers (copepods and other zooplankton) were removed before sub-sampling for Chl a, POC,
plankton taxonomy, and faecal pellets.
Phyto-PAM measurements.
The maximum quantum yield of charge separation in photosystem II Chl
a fluorescence (Φ​PSII-max), the light saturation parameter (Ek), the maximum light utilization coefficient (α​)
and the maximum relative electron transfer rate (rETRmax) were obtained using the Pulse Amplitude Modulated
(PAM) fluorometry method with a Phyto-PAM (Walz, Germany) following established protocols39.
Phyto- and zooplankton analysis. Phytoplankton samples were settled in 50 mL Utermöhl sedimentation
chambers (HYDRO-BIOS©, Kiel, Germany) for 48 h. Phytoplankton was identified and enumerated at 100–600×​
magnification using an inverted Nikon Ti-S light and epifluorescence microscope. The organisms were identified
to the lowest taxonomic level possible under inverted light microscopy, ideally to species level, otherwise to genus
level or grouped into size-classes. Microscopic counts of the dominant organisms at each depth were always well
above the recommended number of 50 per sample. Further, the water column stocks presented in Fig. 2 are integrations of 4 discrete samples from the upper 50 m of the water column, so the total number of specimens counted
per predominating species per water column was >​100 in most cases, reducing the error to <​20%. Randomly
chosen individuals of each phytoplankton species/group were measured and the average cell size was used to
calculate the biovolume from equivalent geometrical shapes40. The biovolume was converted to cellular carbon
content using published carbon conversion factors41.
Mesozooplankton was sampled with a MultiNet (HYDRO-BIOS©, Kiel, Germany) consisting of five nets with
a 0.25 m2 opening and 200 μ​m mesh size at the following depth strata: 0–20, 20–50, 50–200 and 200 m-bottom.
Zooplankton were preserved using 4% formaldehyde solution in seawater buffered with hexamethylentetramine
and identified to species and stage42.
Irradiance measurements.
Solar spectral planar irradiance (Eλ) was measured simultaneously with two
upward-looking Ramses spectral radiometers with cosine collectors (Ramses ACC-VIS, Trios GmbH, Germany).
One measured the incident and the second the transmitted irradiance at the bottom of the ice. These measurements were integrated over the wavelength band of photosynthetically active radiation (PAR, 400–700 nm) and
then used to estimate the transmittance (fraction of transmitted to incident radiation) of EPAR, photosynthetically
active radiation (PAR, 400–700 nm) through the ice and snow. The measurements were conducted continuously
during floes 3 and 4 at a site representative of the thick snow-covered ice43. The same type of sensors were used
to determine the transmittance of EPAR for thin ice (<​0.25 m) in a refrozen lead. In addition, incident irradiance
and irradiance under thick and thin ice was measured with Satlantic HyperOCR hyperspectral radiometers with
cosine collectors, at the surface and mounted to a remotely operated vehicle (ROV) respectively. From these
measurements, transmittance of EPAR was calculated as with the Ramses data.
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Primary production model. A simple primary production model was applied using photosynthesis versus
irradiance data obtained during an Arctic Phaeocystis-dominated phytoplankton bloom15 combined with measured16 and modelled irradiance through thick ice with thick snow cover, thin ice with thin snow cover and open
water taking into account the areal fractions of the three different surface types. A detailed description of the
primary production model can be found in the Supplementary Information.
Ice and snow thickness measurements.
Total ice and snow thickness was measured with a portable
electromagnetic instrument (EM31, Geonics Ltd., Mississauga, Ontario, Canada) mounted on a sledge44. In addition, large-scale surveys of total ice and snow thickness were conducted with a helicopter-borne EM instrument
(HEM, Ferra Dynamics Inc, Mississauga, Ontario, Canada)45. The EM31 and HEM measurements use the same
principle. The height above the bottom of the ice is derived from the strength of electromagnetic induction in the
conductive sea water under the ice. For the HEM measurements, the height of the instrument above the surface
of the ice or snow is determined with a laser altimeter included in the HEM instrument. The EM31 conductivity
values were calibrated with drill-hole measurements and post processed to derive total thickness of ice and snow.
Snow thickness was measured with a GPS snow probe (Magnaprobe, Snow-Hydro, Fairbanks, AK, USA)46. When
used together, these two instruments give the spatial distribution of both the total thickness of the ice and snow
(from EM31) and the snow depth (from Magnaprobe). For direct comparison of the values, and to subtract’ the
snow from the EM31 data, we re-sampled the EM31 data on the Magnaprobe track and applied a Gaussian filter
to the EM31 data. The EM31 and Magnaprobe datasets were median-sampled on a 5 m regular grid. Snow depth
was subtracted from the EM31 values to derive sea-ice thickness.
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Acknowledgements
We are indebted to the captains and crew of RV Lance. This study was supported by the Centre for Ice, Climate
and Ecosystems (ICE) at the Norwegian Polar Institute, the Ministry of Climate and Environment, Norway, the
Research Council of Norway (projects Boom or Bust no. 244646, STASIS no. 221961, CORESAT no. 222681,
CIRFA no. 237906 and AMOS CeO no. 223254), and the Ministry of Foreign Affairs, Norway (project ID
Arctic), the ICE-ARC program of the European Union 7th Framework Program (grant number 603887), the
Polish-Norwegian Research Program operated by the National Centre for Research and Development under the
Norwegian Financial Mechanism 2009–2014 in the frame of Project Contract Pol-Nor/197511/40/2013, CDOMHEAT, and the Ocean Acidification Flagship program within the FRAM- High North Research Centre for
Climate and the Environment, Norway. The ALOS-2 Palsar-2 scene was provided by JAXA under the 4th Research
Announcement program. Radarsat-2 data were provided by NSC/KSAT under the Norwegian-Canadian
Radarsat agreement 2015. Thanks also to Max König, Thomas Kræmer and Malin Johansson for coordination
of satellite acquisitions during N-ICE2015. We thank the Norwegian Meteorological Institute for ice chart data
and the crew from Airlift that undertook the helicopter operations. We kindly acknowledge three anonymous
reviewers and the editors of Scientific Reports for their valuable comments on the manuscript.
Author Contributions
H.S., M.A.G., S.R.H., S.G., G.S., L.H.S., N.H., A.S., P.A. and P.D. designed the field campaign. M.F.M., H.M.K.,
L.M.O., C.J.M., H.H., A.W., A.B., M.S., P.D., M.C., A.F., M.A.G., S.R.L., B.P.K. and P.A. collected and analysed
the biogeochemical data. M.S., P.D., H.M.K. and G.J. performed the Phyto-PAM measurements and analysed
the data. L.C., M.A.G. and S.R.H. conducted the atmospheric measurements. A.T. and J.W. performed the
phytoplankton analysis and S.K. the zooplankton analysis. A.M., A.Ra., L.H.S. and Z.K. performed the
oceanographic measurements. Z.K. and C.P. contributed with the operational model PSY4 from Mercator-Ocean.
A.R., J.A.K., P.I., G.S., M.N., C.M.P. and S.G. contributed sea ice, snow and ice dynamics data. T.T., C.J.M., A.K.P.,
S.R.H., H.M.K., J.K.E. and M.A.G. conducted the irradiance measurements and analysed the data. P.M.W., N.H.
and A.P.D. contributed remote sensing data and the sea ice classification. P.A. drafted the first manuscript; and all
authors contributed to the final version.
Additional Information
Supplementary information accompanies this paper at http://www.nature.com/srep
Competing financial interests: The authors declare no competing financial interests.
How to cite this article: Assmy, P. et al. Leads in Arctic pack ice enable early phytoplankton blooms below
snow-covered sea ice. Sci. Rep. 7, 40850; doi: 10.1038/srep40850 (2017).
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